An apparatus for producing a plasma including a control circuit which is electrically connected to a piezoelectric transformer in order to excite the piezoelectric transformer. A hand-held device that uses the apparatus. The piezoelectric transformer is constructed of several layers. The control circuit is implemented on a circuit board, and the piezoelectric transformer is held over the circuit board by means of a region of a first end. A high voltage is applied to a second free end of the piezoelectric transformer. The plasma is produced at atmospheric pressure.
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1. An apparatus for producing a plasma which can be ignited at atmospheric pressure, comprising:
a printed circuit board;
a control circuit embodied within said printed circuit board, which circuit is electrically connected to a piezoelectric transformer, to excite said piezoelectric transformer, wherein said piezo electric transformer comprises a fixed first end mounted to said printed circuit board; and a free second end, said control circuit operatively arranged to impress a high voltage on said second free end of the piezoelectric transformer and to control a fan to create a current of a working gas for forming the plasma and for cooling the piezoelectric transformer, wherein;
the piezoelectric transformer is constructed from a plurality of layers of dielectric material, wherein the layers are connected to each other, each layer is provided at least partially with a conductor layer and the piezoelectric transformer is freely spaced apart from the printed circuit board by a gap in the region of the first end; and
an electrical connector is guided from the printed circuit board to each lateral face of the piezoelectric transformer and is connected to each terminal pad, which is provided at a vibrational nodal point on each lateral face of the piezoelectric transformer, wherein the vibrational nodal point is closer to the first end than to the second free end of the piezoelectric transformer.
11. A hand-held device for plasma treatment of surfaces, said hand-held device comprising:
a housing;
a voltage source;
a printed circuit board, which is provided in the housing and which has a control circuit in order to excite a piezoelectric transformer wherein the piezoelectric transformer is guided with a first end with a holder above the printed circuit board and, thus, forms a structural unit, and wherein a second free end of the piezoelectric transformer is directed towards an opening in the housing, wherein a high voltage can be impressed on the second free end of the piezoelectric transformer, and the plasma can be ignited at atmospheric pressure;
a working gas for forming the plasma and for cooling the piezoelectric transformer;
wherein the piezoelectric transformer is constructed from a plurality of layers of dielectric material, wherein the layers are connected to each other; and
wherein each layer is provided at least partially with a conductor layer and the piezoelectric transformer is freely spaced apart from the printed circuit board by a gap in a region of the first end; and,
an electrical connector is guided from the printed circuit board to each lateral face of the piezoelectric transformer and is connected to each terminal pad, which is provided at a vibrational nodal point on each lateral face of the piezoelectric transformer, wherein the vibrational nodal point is closer to the first end than to the second free end of the piezoelectric transformer.
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This application is filed under 35 U.S.C. §111(a) and §365(c) as a continuation of International Patent Application PCT/IB2014/058115, filed Jan. 8, 2014, which application claims priority from German Patent Application No. DE 10 2013 100 617.5, filed Jan. 22, 2013, which applications are incorporated herein by reference in their entireties.
The invention relates to a device or an apparatus for producing a plasma. For this purpose there is, in particular, a control circuit that is electrically connected to a piezoelectric transformer, in order to excite said piezoelectric transformer.
Furthermore, the invention relates to a hand-held device for plasma treatment of surfaces. The hand-held device has a housing and a voltage source.
The German patent DE 10 2008 018 827 B4 discloses a device for producing a plasma with a piezoelectric element. The piezoelectric element is equipped with a primary and a secondary region. In this case the primary region of the piezoelectric element is driven with a low voltage and at a high frequency. As a result, the plasma is ignited by the enhancement of the field on the surface of the secondary region of the piezoelectric element. According to the invention, the plasma feed is carried out by means of a counter electrode, located at ground potential, and a gas current, which sweeps past the piezoelectric element. The gas flow allows the plasma to issue from the device.
The German published patent application DE 10 2011 006 764 A1 discloses a piezoelectric transformer with an input-side piezoelectric transducer, an output-side piezoelectric transducer with at least two phases, at least a first electrically non-conductive layer, which is disposed between the input-side piezoelectric transducer and the output-side piezoelectric transducer and which mechanically couples together the input-side piezoelectric transducer and the output-side piezoelectric transducer. Furthermore, at least a second electrically non-conductive layer is disposed between the phases of the output-side piezoelectric transducer.
The U.S. Pat. No. 5,834,882 describes the construction of a multi-layer piezoelectric transformer. A first electroactive member is mechanically coupled to the second electroactive member by means of a bonding layer, which is disposed between a first major face of the first electroactive member and a first major face of the second electroactive member. The bonding layer comprises pre-stressing means for applying compressive stress to the first and the second electroactive members in the longitudinal direction.
The German published patent application DE 10 2009 023 505 A1 discloses a circuit arrangement for a piezoelectric transformer and a method for driving a piezoelectric transformer. The circuit arrangement comprises a driver circuit, a current sensor, a control unit and an oscillator. Furthermore, the circuit arrangement comprises a pulse width modulator. The pulse width modulator is connected between the oscillator and the driver circuit. The oscillator output is connected to an input of the pulse width modulator. A modulator output of the pulse width modulator is connected to the driver signal input. Another modulator output of the pulse width modulator is connected to an additional driver signal input of the driver circuit. An output of the control unit is connected to a modulator control input of the pulse width modulator. A secondary-side voltage, which is used, for example, to trigger a flash, can be tapped at the piezoelectric transformer.
The German published patent application DE 10 2007 055 014 A1 discloses a method for igniting and maintaining a plasma in a gas chamber. The piezoelectric material protrudes into a hollow space, so that the piezoelectric material is caused to resonantly oscillate due to an external electrical excitation. The hollow space contains the gas to be ionized. The electrodes are attached to the exterior of the piezoelectric material. The method lends itself to providing a plasma light source.
The Chinese patent application CN 101259036 A discloses a micro plasma pen for removing freckles. The pen comprises a plasma head for cleaning the skin, a handle housing, a micro transducer, which is arranged in the handle housing, a power output controller and a power module. The pen can deliver a high and variable plasma power output, for which an integrated circuit or a semiconductor chip microprocessor is installed in the handle housing, where in this case the integrated circuit drives a piezoelectric transformer.
The European patent application EP 2 256 835 A2 discloses a pulse generator for a piezoelectric transformer. An output stage of the amplifier drives the piezoelectric transformer at a desired resonant frequency. Two electrodes are connected to the piezoelectric transformer. The voltage, forming at the piezoelectric transformer, is adequate enough to form a dielectric barrier discharge. The generator for the dielectric barrier discharge consists of a tube or a dish. The high voltage electrode is located, for example, in a tube at ground potential.
The German patent DE 10 2005 032 890 B4 discloses a device for producing an atmospheric pressure plasma by means of at least one piezoelectric transformer. Such a transformer is made of a piezoelectric material that is divided in the longitudinal direction into at least one excitation zone and at least one high voltage zone. According to the invention, the piezoelectric transformer has at least one opening that is designed for the gas feed and that is traversed by a gas stream, as a result of which plasma can be produced in the opening.
The German utility model DE 20 2008 008 908 U1 discloses a device for producing an atmospheric pressure plasma. A gas inflow opening, which can be connected to a gas line, and an in-feed line for supplying power to the device are both connected to a power supply device.
The Japanese patent application 2003-297295 discloses a light emitting element that comprises a piezoelectric element. The piezoelectric element is excited by means of an AC voltage.
The German published patent application DE 10 2008 063 052 A1 discloses a device for cleaning the air in a room. The device comprises a housing, in which at least one opening for the intake of ambient air and at least one outlet opening for blowing out the cleaned air are provided. In this case a device for producing plasma can be disposed in the housing in such a way that germs or unpleasant odors can be eliminated.
The article “Piezoelectric Transformers—Circuits and Applications” by C. KAUCZOR, T. SCHULTE, H. GROTSTOLLEN; 47th International Colloquium, Ilmenau University of Applied Sciences, Sep. 23 to 26, 2002. The piezoelectric transformers are a suitable alternative to conventional transformers. The driving voltage is coupled into the primary side; and on the output side (secondary side) the voltage is amplified.
The article “High Efficiency Ozone Production by a Compact Ozonizer Using Piezoelectric Transformer”, by Kenji TERANISHI, Susumu SUZUKI and Haruro ITOH, Chiba Institute of Technology, discloses that the piezoelectric transformer is held at vibration nodal points. The excitation energy is fed into a first half of the piezoelectric transformer. The second half of the piezoelectric transformer is positioned between two electrodes for the barrier discharge. Just the formation of plasma alone on the free end of the piezoelectric transformer is not provided.
The present invention broadly includes an apparatus for producing a plasma including a control circuit which is electrically connected to a piezoelectric transformer in order to excite the piezoelectric transformer. A hand-held device that uses the apparatus. The piezoelectric transformer is constructed of several layers. The control circuit is implemented on a circuit board, and the piezoelectric transformer is held over the circuit board by means of a region of a first end. A high voltage is applied to a second free end of the piezoelectric transformer. The plasma is produced at atmospheric pressure.
The present invention broadly includes an apparatus for producing a plasma with a control circuit, which is electrically connected to a piezoelectric transformer, in order to excite piezoelectric transformer, and a printed circuit board, on which the control circuit is realized. The piezoelectric transformer is mounted with a region of a first end with respect to the printed circuit board, a high voltage can be impressed on a second free end of the piezoelectric transformer, and the plasma can be ignited at atmospheric pressure. A current of a working gas for forming the plasmas and for cooling the piezoelectric transformer flows. The piezoelectric transformer is constructed from a plurality of layers of dielectric material, wherein the layers are connected to each other, wherein each layer is provided at least partially with a conductor layer and the piezoelectric transformer is freely spaced apart from the printed circuit board by a gap in the region of the first end.
The present invention broadly includes an apparatus for producing a plasma which can be ignited at atmospheric pressure including a control circuit, which is electrically connected to a piezoelectric transformer, to excite the piezoelectric transformer, a printed circuit board, on which the control circuit is realized, a region of a first end of the piezoelectric transformer to mount the piezoelectric transformer with respect to the printed circuit board, a high voltage which can be impressed on a second free end of the piezoelectric transformer and a current of a working gas for forming the plasmas and for cooling the piezoelectric transformer. The piezoelectric transformer is constructed from a plurality of layers of dielectric material. The layers are connected to each other and each layer is provided at least partially with a conductor layer and the piezoelectric transformer is freely spaced apart from the printed circuit board by a gap in the region of the first end.
The present invention broadly includes a hand-held device for plasma treatment of surfaces, the hand-held device including a housing, a voltage source and a printed circuit board, which is provided in the housing and which has a control circuit, in order to excite a piezoelectric transformer, wherein the piezoelectric transformer is guided with a first end with a holder above the printed circuit board and, thus, forms a structural unit, and wherein a second free end of the piezoelectric transformer is directed towards an opening in the housing, wherein a high voltage can be impressed on the second free end of the piezoelectric transformer, and the plasma can be ignited at atmospheric pressure. A current of a working gas for forming the plasmas and for cooling the piezoelectric transformer flows. The piezoelectric transformer is constructed from a plurality of layers of dielectric material, wherein the layers are connected to each other. Each layer is provided at least partially with a conductor layer and the piezoelectric transformer is freely spaced apart from the printed circuit board by a gap in a region of the first end.
The present invention broadly includes a hand-held device for plasma treatment of surfaces, the hand-held device including a housing, a voltage source, a printed circuit board, which is provided in the housing and which has a control circuit in order to excite a piezoelectric transformer. The piezoelectric transformer is guided with a first end with a holder above the printed circuit board and, thus, forms a structural unit. A second free end of the piezoelectric transformer is directed towards an opening in the housing. A high voltage can be impressed on the second free end of the piezoelectric transformer and the plasma can be ignited at atmospheric pressure. The hand-held device further includes a current of a working gas for forming the plasma and for cooling the piezoelectric transformer. The piezoelectric transformer is constructed from a plurality of layers of dielectric material. The layers are connected to each other. Each layer is provided at least partially with a conductor layer and the piezoelectric transformer is freely spaced apart from the printed circuit board by a gap in a region of the first end.
The present invention relates to a device for producing atmospheric pressure plasma by means of at least one piezoelectric transformer. Such a transformer is made of a piezoelectric material that is divided in the longitudinal direction into at least one excitation zone and at least one high voltage zone. According to the present invention, the piezoelectric transformer has at least one opening, which is designed for the gas feed and which is traversed by a gas stream, as a result of which plasma can be produced in the opening. According to an additional embodiment of the invention, the directions of polarization of the two zones of the transformer are designed in such a way that plasma, for example, for supplying power to a lamp with corresponding electrodes, is produced at the surface of the high voltage zone itself.
The object of the present invention is to provide a device that is simple and inexpensive, so that the device can be used to produce a plasma at atmospheric pressure.
An additional object of the invention is to propose a hand-held device that is designed for the plasma treatment of surfaces at atmospheric pressure and that is constructed in a cost-effective and simple way.
The inventive device for producing a plasma is characterized by a control circuit, which is electrically connected to the piezoelectric transformer in order to excite said piezoelectric transformer. The piezoelectric transformer is constructed of a plurality of individual layers. The piezoelectric transformer consists of a stack of a plurality of films of a dielectric material, where in this case a conductor track or more specifically a conductive surface is applied to a section of each film. The section of the film with the conductor track is in a section of a first end of the piezoelectric transformer. The individual films are connected to each other in a sintering process; and, in this way the piezoelectric transformer is formed.
The control circuit for driving the piezoelectric transformer is realized on a printed circuit board. As a rule, the piezoelectric transformer is supplied with a voltage, which excites the piezoelectric transformer in accordance with its resonant frequency. The control circuit is also used to adjust the excitation voltage, in the event that the resonant frequency of the piezoelectric transformer changes due to temperature effects and aging processes. Similarly the resonant frequency of the piezoelectric transformer can also drift due to a change in the dielectric properties of the environment or due to the intensity of the discharge that is ignited in the gaseous environment. The piezoelectric transformer is held or rather guided with a region of a first end above the printed circuit board. Owing to the excitation voltage, a high voltage is impressed on a second free end of the piezoelectric transformer. Then on the second free end the plasma ignites at atmospheric pressure. The holder for the piezoelectric transformer holds or more specifically guides said piezoelectric transformer at a vibration nodal point. A gap is formed between the printed circuit board and the piezoelectric transformer, so that the piezoelectric transformer and the printed circuit board are spaced apart from each other. This arrangement makes it possible to eliminate a mechanical damping of the piezoelectric transformer.
The piezoelectric transformer itself is parallel pipe-shaped, where in this case one length and one width of the piezoelectric transformer are greater than one thickness of the piezoelectric transformer. At the same time the multiple layers of the piezoelectric transformer are oriented in such a way that they are more or less perpendicular to the lateral faces of the piezoelectric transformer, said lateral faces being defined by the length and the thickness of the piezoelectric transformer.
An electrical connector for the excitation voltage is provided in each instance at the mutually opposite lateral faces of the piezoelectric transformer. Preferably the electrical connector is mounted at a vibration nodal point of the piezoelectric transformer. The holder for the piezoelectric transformer is also provided at the vibration nodal point of the piezoelectric transformer. In the event that a separate electrical connector for the excitation voltage is guided to the terminal pad, it is sufficient that the holder is made of an elastic material. If the excitation energy for the piezoelectric transformer is supplied by way of the holder, then the material of the holder is elastic and electrically conductive.
A current of a working gas is formed in such a way that it is directed at least from the first end of the piezoelectric transformer, which is mounted on the printed circuit board, to the second free end of the piezoelectric transformer. The current of working gas is used for the formation of the plasma and for cooling the piezoelectric transformer, where in this case the highest thermal power loss occurs at the vibration nodal points. A fan is provided to facilitate the flow of the working gas through the piezoelectric transformer to the second free end.
In a piezoelectric transformer, which is excited at a resonant frequency, at least two vibration nodal points are formed, where in this case both of them are spaced apart from the first end or from the second free end. According to one embodiment, one electrical connector on the printed circuit board is guided in each instance to a respective lateral face of the piezoelectric transformer. The connector is connected to a respective terminal pad, which is provided at a vibration nodal point on each lateral face of the piezoelectric transformer. The terminal pad is mounted at that vibration nodal point that is closer to the first end than to the second free end. Preferably a temperature sensor is provided at this vibration nodal point of the piezoelectric transformer, so that the temperature of the piezoelectric transformer can be monitored, so that the power is switched off, when the temperature exceeds a certain threshold value.
It is particularly advantageous, if the printed circuit board and the piezoelectric transformer form a structural unit. Then this structural unit can be used or more specifically can be installed as an integral whole in a housing.
A hand-held device for the plasma treatment of surfaces has at least a housing and a voltage source. With the plasma output from the hand-held device it is possible to clean a surface and to improve the adhesive properties of paint or adhesive. A printed circuit board with a control circuit for exciting a piezoelectric transformer is arranged in the housing, where in this case the piezoelectric transformer is mounted with a first end on the printed circuit board and, as a result, forms a structural unit with said printed circuit board. A second free end of the piezoelectric transformer is directed towards an opening in the housing. A high voltage is impressed on the second free end of the piezoelectric transformer, so that the plasma is formed at atmospheric pressure. In order to supply power, it is possible to provide a battery and/or a connector for a standard power supply.
The housing bears a fan, with which an air current can be produced through the piezoelectric transformer and towards the opening in the housing. The fan can be formed, as a function of the structural conditions of the housing, as an axial fan.
The hand-held device may be provided with an additional gas port. A working gas other than air can be fed through the gas port to the second free end of the piezoelectric transformer. It is also conceivable that the working gas coming by way of the gas port is mixed with the ambient air.
It is especially advantageous that the device of the invention can be used to produce an atmospheric pressure plasma by means of at least one piezoelectric transformer. The piezoelectric transformer is made of a piezoelectric material that is divided in the longitudinal direction into at least one excitation zone and at least one high voltage zone, where in this case the excitation zone has terminal pads, to which an AC voltage is applied, and wherein mechanical vibrations, which cause electrical fields to build up in the high voltage zone, can be produced in the excitation zone. In addition, the present invention can be integrated into a hand-held device. The hand-held device is easy to transport and, as a result, can reach any desired site without any special effort. Similarly the design of the power supply is simple, a feature that also positively supports its variability with respect to its potential applications.
According to the invention, the volume of the plasma that is produced per unit of time is maximized by geometric structures for local field enhancement. By structuring the high voltage side of the piezoelectric crystal, the volume of the plasma that is produced per unit of time is maximized. The structuring is in a direct positive engagement with the high voltage side of the piezoelectric crystal. The structuring is designed as a separate component that is electrically connected directly to the high voltage side of the piezoelectric crystal. In the region of the field enhancement a working gas (process gas) flows over the piezoelectric crystal (piezoelectric transformer).
Additional advantages and advantageous embodiments of the invention are the subject matter of the following figures and the respective description thereof in which:
The same reference numerals are used for identical or equivalent elements of the invention. The embodiment is shown merely for the purpose of illustrating a way, in which a device for producing a plasma and a hand-held device, into which the device for producing a plasma is installed, can be designed.
Each one of the lateral faces 10 of the piezoelectric transformer 5 has a terminal pad 20, by means of which the piezoelectric transformer 5 is supplied with such a voltage that the piezoelectric transformer 5 oscillates at a resonant frequency. In this respect the terminal pad 20 is located closer to the first end 6 of the piezoelectric transformer 5 than to the second free end 8. As shown in
Although the present description discloses only two embodiments for hand-held devices 100, it is not to be construed as limiting the invention. It should be appreciated that the housing 30 of the hand-held device 100 can take different shapes. The relevant feature is only that an opening 32 is formed in the housing 30, so that the plasma P can issue at atmospheric pressure.
Nettesheim, Stefan, Kuegerl, Georg, Puff, Markus, Korzec, Dariusz, Burger, Dominik, Hoppenthaler, Florian
Patent | Priority | Assignee | Title |
10506699, | Oct 25 2016 | TDK ELECTRONICS AG | Apparatus for generating an atmospheric pressure plasma |
10638590, | Jul 29 2015 | TDK ELECTRONICS AG | Method for frequency control of a piezoelectric transformer and circuit arrangement comprising a piezoelectric transformer |
11071193, | Mar 14 2017 | Relyon Plasma Gmbh | Device for producing a non-thermal atmospheric pressure plasma and active space comprising such a device |
11076475, | Mar 11 2016 | TDK ELECTRONICS AG | Apparatus and method for generating a non-thermal atmospheric pressure plasma |
11101426, | Nov 13 2015 | TDK ELECTRONICS AG | Piezoelectric transformer |
11337295, | Mar 21 2019 | Relyon Plasma Gmbh | Device and component for generating a high voltage or high field strength |
11362259, | Nov 12 2015 | TDK ELECTRONICS AG | Control circuit and method for controlling a piezoelectric transformer |
11476407, | Feb 12 2016 | TDK ELECTRONICS AG | Method for producing a piezoelectric transformer and piezoelectric transformer |
11560011, | Jan 25 2018 | LOHMANN GMBH & CO KG | Method for pretreating materials for flexography by means of mobile low-temperature plasma application |
12075551, | Dec 20 2019 | TDK ELECTRONICS AG | Method of operating a piezoelectric plasma generator |
12102009, | Jun 04 2018 | Relyon Plasma Gmbh; TDK ELECTRONICS AG | Device having an electro-ceramic component |
Patent | Priority | Assignee | Title |
5834882, | May 27 1997 | Face International Corp. | Multi-layer piezoelectric transformer |
6294881, | Jul 08 1997 | Fujitsu Limited | Discharging tube with piezoelectric substrate |
8129653, | Jul 23 2007 | HUETTINGER ELEKTRONIK GMBH + CO KG | Plasma supply device |
8267884, | Oct 07 2005 | Surfx Technologies LLC | Wound treatment apparatus and method |
8710761, | Jun 02 2009 | ams AG | Circuit arrangement for a piezo transformer, and method therefor |
9288886, | May 30 2008 | Colorado State University Research Foundation | Plasma-based chemical source device and method of use thereof |
9314603, | Feb 23 2012 | DRÄGERWERK AG & CO KGAA | Device for disinfecting wound treatment |
9422799, | Jul 25 2013 | «NOVAS ENERGY SERVICES» LTD | Plasma source for generating nonlinear, wide-band, periodic, directed, elastic oscillations and a system and method for stimulating wells, deposits and boreholes using the plasma source |
20090009090, | |||
20090122941, | |||
20090206062, | |||
20100301702, | |||
20120187841, | |||
20120242229, | |||
20120255932, | |||
20130001196, | |||
20130072860, | |||
20130204244, | |||
CN101259036, | |||
DE102005032890, | |||
DE102007055014, | |||
DE102008018827, | |||
DE102008063052, | |||
DE102009023505, | |||
DE102009038563, | |||
DE102011006764, | |||
DE202008008980, | |||
EP1814168, | |||
EP2256835, | |||
JP2003297295, | |||
JP2007281356, | |||
WO2007006298, |
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Jul 20 2015 | KORZEC, DARIUSZ | Relyon Plasma Gmbh | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 036156 | /0283 | |
Jul 20 2015 | BURGER, DOMINIK | Relyon Plasma Gmbh | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 036156 | /0283 | |
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May 26 2016 | PUFF, MARKUS | Epcos AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 040405 | /0075 | |
May 27 2016 | KUEGERL, GEORG | Epcos AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 040405 | /0075 | |
Sep 12 2016 | HOPPENTHALER, FLORIAN | Epcos AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 040405 | /0075 |
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